C5

Cards (20)

  • Conservation of energy principle
    Energy is conserved in chemical reactions. The amount of energy in the universe at the end of a chemical reaction is the same as before the reaction takes place
  • Exothermic reaction
    A reaction where energy is transferred to the surroundings so that the surroundings temperature increases
  • Exothermic reactions
    • Combustion
    • Oxidation reactions
    • Neutralisation (acid + alkali) reactions
  • Endothermic reaction

    A reaction where energy is taken in from the surroundings so the surroundings temperature decreases
  • Endothermic reactions
    • Thermal decomposition
    • Reaction of citric acid and sodium hydrogencarbonate
  • Activation energy
    Minimum amount of energy that particles need to react
  • Reaction profile
    A graph which shows the relative energies of reactants and product, as well as activation energy of the reaction
  • In a chemical reaction, energy is supplied to break bonds and energy is released when bonds are formed
  • Exothermic reaction
    Energy released from forming bonds is greater than that needed to break the bonds
  • Endothermic reaction
    Energy needed to break bonds is greater than energy released making them
  • Energy of reaction = sum of bonds broken - sum of bonds made
  • Cell
    Composed of two electrodes dipped in an electrolyte solution. It produces electricity from a chemical reaction.
  • Battery
    Consists of two or more cells connected in series
  • Voltage obtained from a cell
    Determined by the identities of metals used as electrodes and the identity and concentration of an electrolyte
  • Advantages and disadvantages of using cells and batteries
    • Advantages: more or less cheap, some are rechargeable, a convenient source of electrical energy
    • Disadvantages: harmful chemicals
  • Rechargeable cells
    Chemical reactions are reversed when an external current is supplied
  • Non-rechargeable cells
    Reactants are used up, cannot be recharged
  • Fuel cell
    Supplied by fuel and oxygen to oxidise the fuel to generate electricity
  • Hydrogen fuel cell
    1. Cathode: 2 H2 → 4 H+ + 4 e−
    2. Anode: O2 + 4 H+ + 4 e−→ 2 H2O
    3. Overall: 2 H2 + O2 → 2 H2O
  • Advantages and disadvantages of hydrogen fuel cells
    • Advantages: no pollutants, no recharging
    • Disadvantages: flammable, H2 difficult to store, fossil fuel production, toxic chemicals, expensive production of H2 by electrolysis